Title: Preface: Chemical Forensics

This virtual special issue is devoted to chemical forensics, a developing scientific discipline that aims to provide information to support the attribution of a chemical (or mixture) of interest to its source. This process is carried out through the analysis of the chemical itself or associated material constituents to address investigative, legal or intelligence questions. “Source” refers to how, where and when a chemical was handled or produced. Source information is critical in investigations of incidents of chemicals used for illicit or nefarious purposes, especially when toxic chemicals are used as weapons. The Chemical Weapons Convention (CWC), an international disarmament treaty that entered into force in 1997, prohibits the use of chemicals as weapons. This treaty has 192 States Parties (the countries who have joined the treaty) encompassing more than 98% of the global population and landmass, yet chemical attacks have continued to increase since this treaty was opened for signature to the governments of the world in 1993. The first notorious use of a chemical weapon since 1993 was by the Aum Shinrikyo cult whose sarin attack on the Tokyo subway system in March 1995 killed 13 and drove another 6,000 to seek medical treatment. More recently, over 160more » alleged chemical attacks have been reported in Syria and Iraq with both governments and terrorist groups being accused, and casualties numbering in the thousands. Additionally, recent high profile nerve agent poisoning of dissidents from North Korea and Russia illustrate a willingness to use chemical threat agents (CTAs) with impunity. Given the threat posed by those that choose to use CTAs as weapons, there is a dire need for advancements in chemical forensics that can be used in investigations and inquiries to help find and hold to account, the perpetrators of chemical attacks.« less

@article{osti_1434656,
title = {Preface: Chemical Forensics},
author = {Fraga, Carlos G.},
abstractNote = {This virtual special issue is devoted to chemical forensics, a developing scientific discipline that aims to provide information to support the attribution of a chemical (or mixture) of interest to its source. This process is carried out through the analysis of the chemical itself or associated material constituents to address investigative, legal or intelligence questions. “Source” refers to how, where and when a chemical was handled or produced. Source information is critical in investigations of incidents of chemicals used for illicit or nefarious purposes, especially when toxic chemicals are used as weapons. The Chemical Weapons Convention (CWC), an international disarmament treaty that entered into force in 1997, prohibits the use of chemicals as weapons. This treaty has 192 States Parties (the countries who have joined the treaty) encompassing more than 98% of the global population and landmass, yet chemical attacks have continued to increase since this treaty was opened for signature to the governments of the world in 1993. The first notorious use of a chemical weapon since 1993 was by the Aum Shinrikyo cult whose sarin attack on the Tokyo subway system in March 1995 killed 13 and drove another 6,000 to seek medical treatment. More recently, over 160 alleged chemical attacks have been reported in Syria and Iraq with both governments and terrorist groups being accused, and casualties numbering in the thousands. Additionally, recent high profile nerve agent poisoning of dissidents from North Korea and Russia illustrate a willingness to use chemical threat agents (CTAs) with impunity. Given the threat posed by those that choose to use CTAs as weapons, there is a dire need for advancements in chemical forensics that can be used in investigations and inquiries to help find and hold to account, the perpetrators of chemical attacks.},
doi = {10.1016/j.talanta.2018.04.057},
journal = {Talanta},
number = ,
volume = ,
place = {United States},
year = {2018},
month = {4}
}

This work presents the results for identification of chemical phases obtained by several laboratories as a part of an international nuclear forensic round-robin exercise. In this work powder X-ray diffraction (p-XRD) is regarded as the reference technique. Neutron diffraction produced a superior high-angle diffraction pattern relative to p-XRD. Requiring only small amounts of sample, µ-Raman spectroscopy was used for the first time in this context as a potentially complementary technique to p-XRD. The chemical phases were identified as pure UO 2 in two materials, and as a mixture of UO 2, U 3O 8 and an intermediate species U 3Omore »7 in the third material.« less

For millennia, human transportation was fueled largely through the consumption of biomass (by humans or domestic animals) and to a lesser extent by wind. The 19th century saw a major shift to coal-fueled transportation, with trains and ships powered by steam engines. A second major shift in the fueling of transportation occurred in the 20th century, this time to petroleum. Thus, this transition was not driven by the cost or ease of obtaining energy from oil wells vs. coal mines – indeed, the cost of petroleum has always been higher than coal on a per-unit-energy basis – but rather bymore » the tremendous technical advantages of powering engines with liquids, specifically liquid hydrocarbons.« less

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